Abstract: Apparatus and associated methods relate to maintaining a total current of a switch cell in a digital-to-analog converter at a controllable operating point by adjusting shunt current control signals applied to programmable shunt current sources in opposite polarity with respect to a tail current control signal applied to a programmable tail current source. In an illustrative example, the total current may flow through differential legs of a switch cell. The programmable shunt current sources may, for example, be configured to compensate for adjustments to the programmable tail current source. In an illustrative example, tail current and shunt currents may flow through a pair of cascode transistors. In various examples, controlling the programmable shunt current sources to compensate adjustments to the tail current source may, for example, permit controlled common mode voltage or operating point so as to reduce device voltage stress over a wider dynamic range of output voltages.

Abstract: The present disclosure relates to a sample-and-hold circuit includes a transistor arranged for switching between a sample mode and a hold mode and a bootstrap circuit arranged for maintaining in the sample mode a voltage level between a source terminal and a gate terminal of the transistor independent of the voltage at the source terminal and arranged for switching off the transistor in the hold mode. The bootstrap circuit includes a bootstrap capacitance arranged for being precharged to a given voltage during the hold mode, the bootstrap capacitance being connected between the source terminal and the gate terminal during the sample mode. In one example, the bootstrap circuit comprises a switched capacitor charge pump for generating the given voltage.

Abstract: The present disclosure relates to a sample-and-hold circuit includes a transistor arranged for switching between a sample mode and a hold mode and a bootstrap circuit arranged for maintaining in the sample mode a voltage level between a source terminal and a gate terminal of the transistor independent of the voltage at the source terminal and arranged for switching off the transistor in the hold mode. The bootstrap circuit includes a bootstrap capacitance arranged for being precharged to a given voltage during the hold mode, the bootstrap capacitance being connected between the source terminal and the gate terminal during the sample mode. In one example, the bootstrap circuit comprises a switched capacitor charge pump for generating the given voltage.

Abstract: Methods and devices herein relate to a method for estimating bandwidth mismatch in a time-interleaved A/D converter. An example method includes precharging terminals of capacitors to a first state in each channel of a plurality of channels and sampling a reference analog input voltage signal (Vref) applied via a first switchable path whereby the sampled input voltage signal is received at first terminals of the capacitors. The method further includes setting the second terminals of each channel to a second state. The method also includes applying the reference analog input voltage signal to the first terminals via a second switchable path, and thereby creating on the first terminals a non-zero settling error. The method additionally includes quantizing the settling error to obtain an estimate of the non-zero settling error. The method yet further includes comparing the estimates of the non-zero settling errors and deriving an estimation of the bandwidth mismatch.

Abstract: An ADC includes sampling means for sampling an input voltage signal, comparator(s) for receiving the sampled signal, and a DAC including circuitry for generating a search signal approximating the input signal and a calibration signal. The search signal and the calibration signal are to be applied to a comparator. The ADC also includes a search logic block for receiving a comparator output signal, for providing input to the DAC for generating the search signal, and for producing a digital output signal. Further, the ADC includes a calibration logic block for producing a control signal to control the circuitry of the DAC and including processing means for observing the output signal, for comparing the output signal with a desired output, and for compensating analog non-idealities of the ADC. The DAC circuitry is adapted for generating the calibration signal in accordance with the control signal and with the sampled input signal.

Abstract: The present invention is related to a pipelined analog-to-digital converter, ADC, for converting an analog input signal into a digital signal comprising—a plurality of comparing means having tuneable thresholds for comparing an input signal with; at least two of said given thresholds being different and—a plurality of amplifying circuits,—wherein said plurality of comparing means is configured to form a hierarchical tree structure, said hierarchical tree structure having a plurality of hierarchical levels, wherein at least one of said hierarchical levels is associated with at least one amplifying circuit of said plurality of amplifying circuits, said at least one amplifying circuit generating the input of at least one comparing means at the next hierarchical level and—wherein said plurality of hierarchical levels comprises means for setting said tuneable thresholds in accordance to the output of previous hierarchical level so that non-linear distortion of the preceding hierarchical level is removed.

Abstract: An analog-to-digital (A/D) converter circuit arranged for receiving an analog input signal and for outputting a digital representation of said analog input signal is described.

Abstract: An analog-to-digital (A/D) converter circuit arranged for receiving an analog input signal and for outputting a digital representation of said analog input signal is described.

Abstract: An analog-to-digital converter that uses a comparator based asynchronous binary search is described. The architecture includes a self-clocked (asynchronous) hierarchical binary tree of comparators, each arranged for being provided with a predetermined threshold. The input signal is applied in parallel to all comparators as is the case with flash converters, but the clock is applied to (at least) one comparator only, for example to the first or root comparator. The at least one comparator is further arranged for controlling at least one other comparator of the plurality of comparators.

Abstract: The present invention is related to a pipelined analog-to-digital converter, ADC, for converting an analog input signal into a digital signal comprising—a plurality of comparing means having tuneable thresholds for comparing an input signal with; at least two of said given thresholds being different and—a plurality of amplifying circuits,—wherein said plurality of comparing means is configured to form a hierarchical tree structure, said hierarchical tree structure having a plurality of hierarchical levels, wherein at least one of said hierarchical levels is associated with at least one amplifying circuit of said plurality of amplifying circuits, said at least one amplifying circuit generating the input of at least one comparing means at the next hierarchical level and—wherein said plurality of hierarchical levels comprises means for setting said tuneable thresholds in accordance to the output of previous hierarchical level so that non-linear distortion of the preceding hierarchical level is removed.

Abstract: The present invention is related to an analog-to-digital converter circuit (1) wherein a comparator based asynchronous binary search is used. The architecture comprises a self-clocked (asynchronous) hierarchical binary tree of comparators, each arranged for being provided with a predetermined threshold. The input signal is applied in parallel to all comparators as is the case with flash converters, but the clock is applied to (at least) one comparator (2) only, preferably to the first or root comparator. The at least one comparator (2) is further arranged for controlling at least one other comparator (3) of the plurality of comparators (2, 3, 4).